超级军网无聊,发图
来源:百度文库 编辑:超级军网 时间:2024/04/29 07:42:01
炮弹来打脑壳炮弹来打脑壳
炮炮来拉
没它可不行
在学习中飞过~!~
看看人家的,我伤心
巡航导弹来了
继续来
这是在玩什么,:D .....
玩点弹道导弹
再来一堆
标准standard
标准sm3
来点让各位舒服的
看贴不回,我到你家门口放烟花
好了,完了.继续潜水
不错!看看!!!!
:D :D
]]
LS射得真标准
大大们,继续哈
RIM-161 SM-3 (AEGIS Ballistic Missile Defense)
Standard Missile-3 (SM-3) is being developed as part of the US Navy’s sea-based ballistic missile defense system and will provide theater-wide defense against medium and long range ballistic missiles. In 1992, the Terrier LEAP (Lightweight Exo-Atmospheric Projectile) demonstration program culminated in four flight tests and demonstrated the feasibility of theater-wide ballistic missile defense. This program evolved into today’s SM-3 development program which is based on the SM-2 Block IV airframe and propulsion stack, but incorporates a Third Stage Rocket Motor, a GPS/INS Guidance Section and the SM-3 Kinetic Warhead.
The United States Navy and the Missile Defense Agency are developing Standard Missile-3 (SM-3) as part of the Aegis Ballistic Missile Defense System that will provide allied forces and U.S. protection from short to intermediate range ballistic missiles. The SM-3 Kinetic Warhead (KW) is designed to intercept an incoming ballistic missile outside the earth’s atmosphere. SM-3 is under development by Raytheon at its Missile Systems business unit in Tucson, Arizona.
Configuration
The Aegis BMDS builds upon the Strategic Defense Initiative Organization/Ballistic Missile Defense Organization (SDIO/ BMDO) investment in Lightweight ExoAtmospheric Projectile (LEAP) technology and the Navy’s Aegis weapon system including Standard Missile and MK41 Vertical Launching System currently deployed on many U.S. Navy and international surface combatants.
The SM-3 KW is a highly modular, compact, space tested kinetic warhead designed to defend against short to intermediate range ballistic missile attacks. Raytheon has engineered two prior generations of LEAP designs starting in 1985 under contracts with SDIO and BMDO. This third generation LEAP design integrates the teamed experience of Raytheon and Boeing in KW designs and Alliant Techsystems’ expertise in Solid Divert and Attitude Control. The SM-3 KW design features a large aperture wide field of view long wave infrared seeker that provides acquisition ranges greater than 300 km against typical ballistic missile threats. Seeker pointing and intercept guidance are supported by a production IFOG Inertial Measurement Unit and wooden round simplicity of the SDACS propulsion providing over 2 miles of terminal divert capability. The KW includes a fully encrypted data downlink capability for full engineering evaluation of KW performance and to support rapid kill assessment.
The SM-3 evolves from the proven SM-2 Block IV design. SM-3 uses the same booster and dual thrust rocket motor as the Block IV missile for the first and second stages and the same steering control section and midcourse missile guidance for maneuvering in the atmosphere. To support the extended range of an exo-atmospheric intercept, additional missile thrust is provided in a new third stage for the SM-3 missile, containing a dual pulse rocket motor for the early exo-atmospheric phase of flight and a Lightweight Exo-Atmospheric Projectile (LEAP) Kinetic Warhead (KW) for the intercept phase. Upon second stage separation, the first pulse burn of the Third Stage Rocket Motor (TSRM) provides the axial thrust to maintain the missile’s trajectory into the exo-atmosphere. Upon entering the exo-atmosphere, the third stage coasts. The TSRM’s attitude control system maneuvers the third stage to eject the nosecone, exposing the KW’s Infrared (IR) seeker. If the third stage requires a course correction for an intercept, the rocket motor begins the second pulse burn. Upon completion of the second pulse burn, the IR seeker is calibrated and the KW ejects. The KW possesses its own attitude control system and guidance commands are acted upon by a solid divert propulsion system. The IR seeker acquires the target. Tracking information is continuously transmitted to the guidance assembly which controls the divert propulsion system.
Discrimination algorithms enable defense systems to compare objects in a target scene to determine which to intercept. Increasingly complex threats with separated target elements, countermeasures, and debris, require advanced signal processing and discrimination algorithms to identify object features needed to provide robust target selection. SM-3 has flown and demonstrated fundamental discrimination capability for unitary threats.
Computer program design upgrades are in work to expand the current selection accuracy and add capability against more stressing unitary and separating target scenes using target features observed by the Aegis radar system and the KW LWIR seeker to optimize selection confidence. Leveraging off discrimination architecture used across Raytheon’s missile programs, SM-3 continues to evolve an integrated discrimination design for insertion with the current seeker design and each of the sensing and signal processor upgrades available to counter advancing threats.
Raytheon is working closely with the Navy to ensure that SM-3, based on legacy Standard tactical missile designs, stands ready to provide immediate emergency Aegis BMD capability against preponderant threats. The SM-3 Block I KW configuration features a single color LWIR seeker, a solid DACS propulsion, target identification and discrimination, and lethal intercept accuracy.
In 2004 the Pentagon decided to embark on the development in fiscal 2007 of an enhanced version of the Standard Missile 3 interceptor.
Flight Test Program
The Aegis BMD flight test program has achieved four successful intercepts in five attempts. These flight tests have demonstrated the capability to intercept short-range, simple unitary targets in both descent and ascent phases of flight, and in the case of FM-6, have shown the capability to destroy the target warhead.
The AEGIS LEAP Intercept (ALI) program has demonstrated the design capabilities of the SM-3 KW with a series of ground and flight tests. ALI culminated in two successful ballistic missile intercepts on the first two engagement missions. Flight Mission Two (FM-2) flown on 25 January 2002 and Flight Mission Three (FM-3) on 13 June 2002 were completely successful allowing the program to proceed into testbed development.
Aegis BMD testbed initiated a series of increasingly complex missions to evaluate SM-3 design capability while the program prepares for potential emergency tactical availability. The first mission of this test series, Flight Mission Four (FM-4), was flown on 21 November 2002 resulting in a third successful intercept for the program. This mission demonstrated the ship’s crew and system response times necessary to track, engage, and intercept a ballistic missile target early in flight during its ascent phase (prior to apogee). FM-4 also provided a key verification of SM-3’s capability to accurately hit the target at a predefined point for lethality which, for this test, was forward of the target center. The KW impacted within centimeters of the aimpoint, completely destroying the target avionics section.
In FY03, two intercept attempts of a unitary target in its ascent phase were conducted. In the first test, the Aegis BMD element successfully intercepted the target. Using a newly designed divert system onboard the SM-3 missile, the Aegis BMD failed to intercept the target in the second FY03 test. The cause of the failed intercept has been attributed to a malfunction in a divert valve in the attitude control system onboard the kinetic warhead. Testing continued based on the consistent performance of the sustained pulse mode, while mitigation options were evaluated.
In FY03, the operational robustness of the Aegis BMD Block 2004 test program was enhanced by increased operational realism in the test strategy. Efforts to add operational realism as part of the developmental test strategy provide significant risk reduction in advance of operational testing and potential deployment of the element. The planned growth in flight test realism is consistent with the maturity of the system. Although the Block 2004 flight test plan include many operationally realistic aspects, some important operational scenarios remain untested by the end of the Block 2004 test program. These include multiple simultaneous engagements and separating targets. Development and integration of critical technologies pertaining to threat discrimination (e.g., AWS discrimination logic, radar and infrared seeker upgrades) and missile propulsion (e.g., kinetic warhead divert system, SM-3 booster propulsion) could improve operational capability as they are introduced in Block 2004 and subsequent upgrades.
On 18 June 2003. A developmental Standard Missile-3 (SM-3) is launched from the U.S. Navy cruiser, USS Lake Erie (CG-70), in a Missile Defense Agency test, Wednesday, near Kauai, Hawaii. The test was the latest in a series aimed at developing a sea-based defense against short to medium range ballistic missile threats.
On 11 December 2003 Flight Mission-6 (FM-6) involved the detection and tracking of an Aries medium-range target missile launched from the Pacific Missile Range Facility (PMRF), Kauai, Hawaii at 8:10am HST (1:10pm EST). Approximately two minutes after target launch, a developmental Standard Missile-3 (SM-3) was launched from the Aegis Ballistic Missile Defense cruiser the USS LAKE ERIE (CG 70). Approximately two minutes later the SM-3 successfully intercepted the target missile with Òhit to killÓ technology, using only the force of the direct collision to destroy the target. This was the fourth successful intercept for Aegis BMD and SM-3.
Raytheon's next hit-to-kill success with the sea-based STANDARD Missile-3 occurred on 11 December 2003. Between January 2002 and late 2004, the Aegis BMD system had successfully intercepted targets in space four times with SM-3. In all the flight tests, the SM-3 was launched from a US Navy cruiser under increasingly realistic, operational conditions.
On 24 February 2005 the Aegis Ballistic Missile Defense (BMD) Weapon System and Standard Missile-3 (SM-3) destroyed a ballistic missile outside the earth's atmosphere during an Aegis BMD Program flight test over the Pacific Ocean. The Feb. 24 mission -- the fifth successful intercept for SM-3 -- was the first firing of the Aegis BMD "Emergency Deployment" capability using operational versions of the SM-3 Block I missile and Aegis BMD Weapon System. This was also the first test to exercise SM-3's third stage rocket motor (TSRM) single-pulse mode. The TSRM has two pulses, which can be ignited independently, providing expansion of the ballistic missile engagement battlespace. The SM-3 was launched from the Aegis BMD cruiser USS Lake Erie (CG 70) and hit a target missile that had been launched from the U.S. Navy's Pacific Missile Range Facility on Kauai, Hawaii.
On 17 November 2005 a test involved for the first time a "separating" target, meaning that the target warhead separated from its booster rocket requiring the interceptor to distinguish between the body of the missile and the actual warhead. The interceptor missile was launched from the Pearl Harbor-based Aegis cruiser USS Lake Erie (CG 70). The target was intercepted more than 100 miles in space above the Pacific Ocean and 375 miles northwest of Kauai.
A Standard Missile-3 (SM-3) was launched on March 8, 2006 from the USS Lake Erie (CG 70) in a Missile Defense Agency and Japan Defense Agency joint test in the Pacific. The cooperative test demonstrated the SM-3 with a Japan-designed advanced nosecone. The flight test, a milestone in a joint cooperative research project, is an example of the ongoing coordination between the U.S. and Japan on missile defense efforts.
Deployment
To fulfill the sea-based portion of the initial missile defense capabilities, the MDA is developing Aegis BMD in close coordination with the Navy and Naval Sea Systems Command. Aegis BMD Block 2004 consists of two major contributions to BMDS. The first contribution is Aegis DDG-51 Class Destroyers equipped for Long Range Surveillance and Track (LRS&T). LRS&T provides a capability to detect and track LRBMs and to report the track data to the BMDS. This capability assists in the sharing of tracking data to cue other BMDS sensors and provides fire control support to engagement elements. LRS&T is the first Aegis BMD delivery and is part of the Initial Defensive Operations (IDO), which went on alert in 2004.
The second contribution is Aegis CG-47 Class Cruisers equipped with the LRS&T capability, but also armed with the new SM-3, capable of intercepting short and medium range ballistic missile threats in the midcourse phase of flight. By 2005, full Aegis BMD Block 2004 functionality will be implemented in the first set of Aegis Cruisers. In the future, Aegis BMD capability will evolve to defeat longer range ballistic missiles.
Raytheon delivered five SM-3 operational rounds to the Missile Defense Agency in 2004. The program is transitioning to production, with Kinetic Warhead seeker and final integration occurring in Raytheon's state-of-the-art Kill Vehicle manufacturing facility, alongside the Exoatmospheric Kill Vehicle. Final assembly and test occur in Camden, AK. As part of the initial deployment of the BMDS, five Pacific Fleet Aegis Destroyers had operational LRS&T upgrades installed by the end of 2004. There will be a total of 15 LRS&T Aegis Destroyers and 3 Aegis BMD engagement Cruisers by the end of CY 06.
In October 2004 Raytheon Company began delivering STANDARD Missile-3 (SM-3) initial deployment rounds to the Missile Defense Agency. SM-3 is a key element of the Aegis Ballistic Missile Defense System and builds on the existing fleet of Aegis cruisers and destroyers. This is a critical milestone for Raytheon and for the country. These deployment rounds move the US Navy one step closer to providing a sea-based defense against short- to intermediate-range ballistic missile threats. The delivery of SM-3 supports the administration's commitment to provide a sea-based missile defense capability.
Aegis BMD went to sea on 30 September 2004, able to track an ICBM and to communicate that information to the Ballistic Missile Defense System. The Navy added firepower to Aegis BMD with the SM-3 missile. It is able to participate in the defense of not only the US, but of allies, friends and deployed troops against short-medium range ballistic missiles around the globe. Because naval forces are inherently mobile and capable of multiple missions, Aegis BMD will provide a broad array of options to operational commanders responding to a wide variety of dynamic world situations.
Japan Maritime Self Defense Force Deployment
The potential for allied cooperation in development and procurement of a BMD system is real. In December 2003, through a formal Cabinet Decision, the Government of Japan became the first ally to decide to proceed with the acquisition of a multi-layered BMD system, basing its initial capability on upgrades of its Aegis Destroyers and acquisition of the SM-3 missile. The two nations began the research program in 1999 for a system to launch interceptors from Aegis destroyers. Japan has spent 15.6 billion yen up to fiscal 2003. The AEGIS Weapon System and Standard missiles will be used on JMSDF ships and will provide, in concert with JSDF PAC-3 Patriot missiles, the initial ballistic missile defense for mainland Japan. Japan already has the upgraded AEGIS Weapon System and SM-3 Block IA Standard missiles in its inventory and will have no difficulty absorbing the additional upgraded Weapon System and missiles.
The first Aegis BMD installation in the Japan Maritime Self Defense Force was scheduled for the fall of 2007. In addition, Japan will upgrade their Patriot units with PAC-3 missiles and improved ground support equipment. The US has worked closely with Japan since 1999 to design and develop advanced components for the SM-3 missile. This project would culminate in flight tests of SM-3 variant missiles in 2005 and 2006.
On 5 May 2004, the Defense Security Cooperation Agency notified Congress of a possible Foreign Military Sale to Japan of SM-3 Block 1A Standard Missiles as well as associated equipment and services. The total value, if all options are exercised, could be as high as $725 million.
On 29 June 2005, the Defense Security Cooperation Agency notified Congress of a possible Foreign Military Sale to Japan of nine SM-3 Block IA Standard missiles with MK 21 Mod 2 canisters, as well as associated equipment and services. The total value, if all options are exercised, could be as high as $387 million. The Government of Japan has requested a possible sale of nine SM-3 Block IA Standard missiles with MK 21 Mod 2 canisters, Ballistic Missile Defense (BMD) upgrades to one AEGIS Weapon System, AEGIS BMD Vertical Launch System ORDALTs, containers, spare and repair parts, publications, documentation, supply support, U.S. Government and contractor technical assistance and other related elements of logistics support. The estimated cost is $387 million.
Standard Missile-3 (SM-3) is being developed as part of the US Navy’s sea-based ballistic missile defense system and will provide theater-wide defense against medium and long range ballistic missiles. In 1992, the Terrier LEAP (Lightweight Exo-Atmospheric Projectile) demonstration program culminated in four flight tests and demonstrated the feasibility of theater-wide ballistic missile defense. This program evolved into today’s SM-3 development program which is based on the SM-2 Block IV airframe and propulsion stack, but incorporates a Third Stage Rocket Motor, a GPS/INS Guidance Section and the SM-3 Kinetic Warhead.
The United States Navy and the Missile Defense Agency are developing Standard Missile-3 (SM-3) as part of the Aegis Ballistic Missile Defense System that will provide allied forces and U.S. protection from short to intermediate range ballistic missiles. The SM-3 Kinetic Warhead (KW) is designed to intercept an incoming ballistic missile outside the earth’s atmosphere. SM-3 is under development by Raytheon at its Missile Systems business unit in Tucson, Arizona.
Configuration
The Aegis BMDS builds upon the Strategic Defense Initiative Organization/Ballistic Missile Defense Organization (SDIO/ BMDO) investment in Lightweight ExoAtmospheric Projectile (LEAP) technology and the Navy’s Aegis weapon system including Standard Missile and MK41 Vertical Launching System currently deployed on many U.S. Navy and international surface combatants.
The SM-3 KW is a highly modular, compact, space tested kinetic warhead designed to defend against short to intermediate range ballistic missile attacks. Raytheon has engineered two prior generations of LEAP designs starting in 1985 under contracts with SDIO and BMDO. This third generation LEAP design integrates the teamed experience of Raytheon and Boeing in KW designs and Alliant Techsystems’ expertise in Solid Divert and Attitude Control. The SM-3 KW design features a large aperture wide field of view long wave infrared seeker that provides acquisition ranges greater than 300 km against typical ballistic missile threats. Seeker pointing and intercept guidance are supported by a production IFOG Inertial Measurement Unit and wooden round simplicity of the SDACS propulsion providing over 2 miles of terminal divert capability. The KW includes a fully encrypted data downlink capability for full engineering evaluation of KW performance and to support rapid kill assessment.
The SM-3 evolves from the proven SM-2 Block IV design. SM-3 uses the same booster and dual thrust rocket motor as the Block IV missile for the first and second stages and the same steering control section and midcourse missile guidance for maneuvering in the atmosphere. To support the extended range of an exo-atmospheric intercept, additional missile thrust is provided in a new third stage for the SM-3 missile, containing a dual pulse rocket motor for the early exo-atmospheric phase of flight and a Lightweight Exo-Atmospheric Projectile (LEAP) Kinetic Warhead (KW) for the intercept phase. Upon second stage separation, the first pulse burn of the Third Stage Rocket Motor (TSRM) provides the axial thrust to maintain the missile’s trajectory into the exo-atmosphere. Upon entering the exo-atmosphere, the third stage coasts. The TSRM’s attitude control system maneuvers the third stage to eject the nosecone, exposing the KW’s Infrared (IR) seeker. If the third stage requires a course correction for an intercept, the rocket motor begins the second pulse burn. Upon completion of the second pulse burn, the IR seeker is calibrated and the KW ejects. The KW possesses its own attitude control system and guidance commands are acted upon by a solid divert propulsion system. The IR seeker acquires the target. Tracking information is continuously transmitted to the guidance assembly which controls the divert propulsion system.
Discrimination algorithms enable defense systems to compare objects in a target scene to determine which to intercept. Increasingly complex threats with separated target elements, countermeasures, and debris, require advanced signal processing and discrimination algorithms to identify object features needed to provide robust target selection. SM-3 has flown and demonstrated fundamental discrimination capability for unitary threats.
Computer program design upgrades are in work to expand the current selection accuracy and add capability against more stressing unitary and separating target scenes using target features observed by the Aegis radar system and the KW LWIR seeker to optimize selection confidence. Leveraging off discrimination architecture used across Raytheon’s missile programs, SM-3 continues to evolve an integrated discrimination design for insertion with the current seeker design and each of the sensing and signal processor upgrades available to counter advancing threats.
Raytheon is working closely with the Navy to ensure that SM-3, based on legacy Standard tactical missile designs, stands ready to provide immediate emergency Aegis BMD capability against preponderant threats. The SM-3 Block I KW configuration features a single color LWIR seeker, a solid DACS propulsion, target identification and discrimination, and lethal intercept accuracy.
In 2004 the Pentagon decided to embark on the development in fiscal 2007 of an enhanced version of the Standard Missile 3 interceptor.
Flight Test Program
The Aegis BMD flight test program has achieved four successful intercepts in five attempts. These flight tests have demonstrated the capability to intercept short-range, simple unitary targets in both descent and ascent phases of flight, and in the case of FM-6, have shown the capability to destroy the target warhead.
The AEGIS LEAP Intercept (ALI) program has demonstrated the design capabilities of the SM-3 KW with a series of ground and flight tests. ALI culminated in two successful ballistic missile intercepts on the first two engagement missions. Flight Mission Two (FM-2) flown on 25 January 2002 and Flight Mission Three (FM-3) on 13 June 2002 were completely successful allowing the program to proceed into testbed development.
Aegis BMD testbed initiated a series of increasingly complex missions to evaluate SM-3 design capability while the program prepares for potential emergency tactical availability. The first mission of this test series, Flight Mission Four (FM-4), was flown on 21 November 2002 resulting in a third successful intercept for the program. This mission demonstrated the ship’s crew and system response times necessary to track, engage, and intercept a ballistic missile target early in flight during its ascent phase (prior to apogee). FM-4 also provided a key verification of SM-3’s capability to accurately hit the target at a predefined point for lethality which, for this test, was forward of the target center. The KW impacted within centimeters of the aimpoint, completely destroying the target avionics section.
In FY03, two intercept attempts of a unitary target in its ascent phase were conducted. In the first test, the Aegis BMD element successfully intercepted the target. Using a newly designed divert system onboard the SM-3 missile, the Aegis BMD failed to intercept the target in the second FY03 test. The cause of the failed intercept has been attributed to a malfunction in a divert valve in the attitude control system onboard the kinetic warhead. Testing continued based on the consistent performance of the sustained pulse mode, while mitigation options were evaluated.
In FY03, the operational robustness of the Aegis BMD Block 2004 test program was enhanced by increased operational realism in the test strategy. Efforts to add operational realism as part of the developmental test strategy provide significant risk reduction in advance of operational testing and potential deployment of the element. The planned growth in flight test realism is consistent with the maturity of the system. Although the Block 2004 flight test plan include many operationally realistic aspects, some important operational scenarios remain untested by the end of the Block 2004 test program. These include multiple simultaneous engagements and separating targets. Development and integration of critical technologies pertaining to threat discrimination (e.g., AWS discrimination logic, radar and infrared seeker upgrades) and missile propulsion (e.g., kinetic warhead divert system, SM-3 booster propulsion) could improve operational capability as they are introduced in Block 2004 and subsequent upgrades.
On 18 June 2003. A developmental Standard Missile-3 (SM-3) is launched from the U.S. Navy cruiser, USS Lake Erie (CG-70), in a Missile Defense Agency test, Wednesday, near Kauai, Hawaii. The test was the latest in a series aimed at developing a sea-based defense against short to medium range ballistic missile threats.
On 11 December 2003 Flight Mission-6 (FM-6) involved the detection and tracking of an Aries medium-range target missile launched from the Pacific Missile Range Facility (PMRF), Kauai, Hawaii at 8:10am HST (1:10pm EST). Approximately two minutes after target launch, a developmental Standard Missile-3 (SM-3) was launched from the Aegis Ballistic Missile Defense cruiser the USS LAKE ERIE (CG 70). Approximately two minutes later the SM-3 successfully intercepted the target missile with Òhit to killÓ technology, using only the force of the direct collision to destroy the target. This was the fourth successful intercept for Aegis BMD and SM-3.
Raytheon's next hit-to-kill success with the sea-based STANDARD Missile-3 occurred on 11 December 2003. Between January 2002 and late 2004, the Aegis BMD system had successfully intercepted targets in space four times with SM-3. In all the flight tests, the SM-3 was launched from a US Navy cruiser under increasingly realistic, operational conditions.
On 24 February 2005 the Aegis Ballistic Missile Defense (BMD) Weapon System and Standard Missile-3 (SM-3) destroyed a ballistic missile outside the earth's atmosphere during an Aegis BMD Program flight test over the Pacific Ocean. The Feb. 24 mission -- the fifth successful intercept for SM-3 -- was the first firing of the Aegis BMD "Emergency Deployment" capability using operational versions of the SM-3 Block I missile and Aegis BMD Weapon System. This was also the first test to exercise SM-3's third stage rocket motor (TSRM) single-pulse mode. The TSRM has two pulses, which can be ignited independently, providing expansion of the ballistic missile engagement battlespace. The SM-3 was launched from the Aegis BMD cruiser USS Lake Erie (CG 70) and hit a target missile that had been launched from the U.S. Navy's Pacific Missile Range Facility on Kauai, Hawaii.
On 17 November 2005 a test involved for the first time a "separating" target, meaning that the target warhead separated from its booster rocket requiring the interceptor to distinguish between the body of the missile and the actual warhead. The interceptor missile was launched from the Pearl Harbor-based Aegis cruiser USS Lake Erie (CG 70). The target was intercepted more than 100 miles in space above the Pacific Ocean and 375 miles northwest of Kauai.
A Standard Missile-3 (SM-3) was launched on March 8, 2006 from the USS Lake Erie (CG 70) in a Missile Defense Agency and Japan Defense Agency joint test in the Pacific. The cooperative test demonstrated the SM-3 with a Japan-designed advanced nosecone. The flight test, a milestone in a joint cooperative research project, is an example of the ongoing coordination between the U.S. and Japan on missile defense efforts.
Deployment
To fulfill the sea-based portion of the initial missile defense capabilities, the MDA is developing Aegis BMD in close coordination with the Navy and Naval Sea Systems Command. Aegis BMD Block 2004 consists of two major contributions to BMDS. The first contribution is Aegis DDG-51 Class Destroyers equipped for Long Range Surveillance and Track (LRS&T). LRS&T provides a capability to detect and track LRBMs and to report the track data to the BMDS. This capability assists in the sharing of tracking data to cue other BMDS sensors and provides fire control support to engagement elements. LRS&T is the first Aegis BMD delivery and is part of the Initial Defensive Operations (IDO), which went on alert in 2004.
The second contribution is Aegis CG-47 Class Cruisers equipped with the LRS&T capability, but also armed with the new SM-3, capable of intercepting short and medium range ballistic missile threats in the midcourse phase of flight. By 2005, full Aegis BMD Block 2004 functionality will be implemented in the first set of Aegis Cruisers. In the future, Aegis BMD capability will evolve to defeat longer range ballistic missiles.
Raytheon delivered five SM-3 operational rounds to the Missile Defense Agency in 2004. The program is transitioning to production, with Kinetic Warhead seeker and final integration occurring in Raytheon's state-of-the-art Kill Vehicle manufacturing facility, alongside the Exoatmospheric Kill Vehicle. Final assembly and test occur in Camden, AK. As part of the initial deployment of the BMDS, five Pacific Fleet Aegis Destroyers had operational LRS&T upgrades installed by the end of 2004. There will be a total of 15 LRS&T Aegis Destroyers and 3 Aegis BMD engagement Cruisers by the end of CY 06.
In October 2004 Raytheon Company began delivering STANDARD Missile-3 (SM-3) initial deployment rounds to the Missile Defense Agency. SM-3 is a key element of the Aegis Ballistic Missile Defense System and builds on the existing fleet of Aegis cruisers and destroyers. This is a critical milestone for Raytheon and for the country. These deployment rounds move the US Navy one step closer to providing a sea-based defense against short- to intermediate-range ballistic missile threats. The delivery of SM-3 supports the administration's commitment to provide a sea-based missile defense capability.
Aegis BMD went to sea on 30 September 2004, able to track an ICBM and to communicate that information to the Ballistic Missile Defense System. The Navy added firepower to Aegis BMD with the SM-3 missile. It is able to participate in the defense of not only the US, but of allies, friends and deployed troops against short-medium range ballistic missiles around the globe. Because naval forces are inherently mobile and capable of multiple missions, Aegis BMD will provide a broad array of options to operational commanders responding to a wide variety of dynamic world situations.
Japan Maritime Self Defense Force Deployment
The potential for allied cooperation in development and procurement of a BMD system is real. In December 2003, through a formal Cabinet Decision, the Government of Japan became the first ally to decide to proceed with the acquisition of a multi-layered BMD system, basing its initial capability on upgrades of its Aegis Destroyers and acquisition of the SM-3 missile. The two nations began the research program in 1999 for a system to launch interceptors from Aegis destroyers. Japan has spent 15.6 billion yen up to fiscal 2003. The AEGIS Weapon System and Standard missiles will be used on JMSDF ships and will provide, in concert with JSDF PAC-3 Patriot missiles, the initial ballistic missile defense for mainland Japan. Japan already has the upgraded AEGIS Weapon System and SM-3 Block IA Standard missiles in its inventory and will have no difficulty absorbing the additional upgraded Weapon System and missiles.
The first Aegis BMD installation in the Japan Maritime Self Defense Force was scheduled for the fall of 2007. In addition, Japan will upgrade their Patriot units with PAC-3 missiles and improved ground support equipment. The US has worked closely with Japan since 1999 to design and develop advanced components for the SM-3 missile. This project would culminate in flight tests of SM-3 variant missiles in 2005 and 2006.
On 5 May 2004, the Defense Security Cooperation Agency notified Congress of a possible Foreign Military Sale to Japan of SM-3 Block 1A Standard Missiles as well as associated equipment and services. The total value, if all options are exercised, could be as high as $725 million.
On 29 June 2005, the Defense Security Cooperation Agency notified Congress of a possible Foreign Military Sale to Japan of nine SM-3 Block IA Standard missiles with MK 21 Mod 2 canisters, as well as associated equipment and services. The total value, if all options are exercised, could be as high as $387 million. The Government of Japan has requested a possible sale of nine SM-3 Block IA Standard missiles with MK 21 Mod 2 canisters, Ballistic Missile Defense (BMD) upgrades to one AEGIS Weapon System, AEGIS BMD Vertical Launch System ORDALTs, containers, spare and repair parts, publications, documentation, supply support, U.S. Government and contractor technical assistance and other related elements of logistics support. The estimated cost is $387 million.
献上鸟语!!!
睡醒继续,休息一下,看个图
看看,对面的那条船怎么那么眼熟
俄亥俄,天朝虾米时候才有这么舒服的艇啊
]]
怪物来了,相信对超大来说已经不陌生了
Mk 31 RAM - Mk-31 RAM
The Mk-31 RAM, co-developed by the United States and Germany, is a shipboard anti-missile weapon system that provides high-firepower and multiple simultaneous engagement capability against incoming threats. It is suitable for ships of all-sizes. Up to 21 Mk-44 Guided Missile Round Packs and one Mk-49 Guided Missile Launching System comprise the Mk-31 RAM weapon system. Ship's sensors provide the necessary target and pointing data required to engage anti-ship missiles, fixed and rotary wing aircraft, and surface craft.
The Raytheon company is upgrading the Mk-31 weapon system via missile software updates. The software updates, called the HAS upgrade, will enable RAM missiles to engage helicopters, aircraft and surface targets in addition to anti-ship missiles, which are the weapon system's primary target. HAS update will allow to conduct engagements even in high clutter environments. (HAS is after Helicopter , Aircraft and Surface craft)
The RAM weapon system is planned for installation, or already delivered and installed, on 83 US Navy and 28 German Navy ships. The Republic of Korea also has ordered RAM through four direct commercial sales awarded to Raytheon. The Greek Navy is the latest customer for the RAM weapon system with an in-service date expected soon, as of October 2004.
In October 2004, the Republic of Korea Navy ordered three RAM systems worth $25 million for the KDX-III class destroyers. These ships have been planned to be outfitted with US Navy's AEGIS weapon system.
Raytheon was awarded a $45 million contract March 22, 2005, for production of 70 launching canisters, 65 RAM Mk 44 Mod 3 all up round tactical guided missile round packs (GMRP), 25 RAM Block 1/HAS Telemeter GMRPs and associated equipment in support of the United States government. Production work was carried out in both partner countries by Raytheon in Tucson, Arizona (United States) and by RAMSYS GmbH in Ottobrunn (Germany). This contract was the eighth production installment featuring Block 1 GMRP configuration.
In February 2006 the Egyptian Navy selected the Mk 31 Rolling Airframe Missile (RAM) to protects its Ambassador III fast missile craft from aircraft, cruise missiles, high speed surface crafts and helicopters.
The Mk-31 RAM, co-developed by the United States and Germany, is a shipboard anti-missile weapon system that provides high-firepower and multiple simultaneous engagement capability against incoming threats. It is suitable for ships of all-sizes. Up to 21 Mk-44 Guided Missile Round Packs and one Mk-49 Guided Missile Launching System comprise the Mk-31 RAM weapon system. Ship's sensors provide the necessary target and pointing data required to engage anti-ship missiles, fixed and rotary wing aircraft, and surface craft.
The Raytheon company is upgrading the Mk-31 weapon system via missile software updates. The software updates, called the HAS upgrade, will enable RAM missiles to engage helicopters, aircraft and surface targets in addition to anti-ship missiles, which are the weapon system's primary target. HAS update will allow to conduct engagements even in high clutter environments. (HAS is after Helicopter , Aircraft and Surface craft)
The RAM weapon system is planned for installation, or already delivered and installed, on 83 US Navy and 28 German Navy ships. The Republic of Korea also has ordered RAM through four direct commercial sales awarded to Raytheon. The Greek Navy is the latest customer for the RAM weapon system with an in-service date expected soon, as of October 2004.
In October 2004, the Republic of Korea Navy ordered three RAM systems worth $25 million for the KDX-III class destroyers. These ships have been planned to be outfitted with US Navy's AEGIS weapon system.
Raytheon was awarded a $45 million contract March 22, 2005, for production of 70 launching canisters, 65 RAM Mk 44 Mod 3 all up round tactical guided missile round packs (GMRP), 25 RAM Block 1/HAS Telemeter GMRPs and associated equipment in support of the United States government. Production work was carried out in both partner countries by Raytheon in Tucson, Arizona (United States) and by RAMSYS GmbH in Ottobrunn (Germany). This contract was the eighth production installment featuring Block 1 GMRP configuration.
In February 2006 the Egyptian Navy selected the Mk 31 Rolling Airframe Missile (RAM) to protects its Ambassador III fast missile craft from aircraft, cruise missiles, high speed surface crafts and helicopters.
Rif - Rif
The S-300F, SA-N-6 Grumble NATO-codename and Rif Russian nickname, is a derivative of proven S-300 Surface-to-Air Missile (SAM) system designed to protect surface ships against advanced airborne threats. The system can engage up to 6 targets simultaneously with 2 missiles per target ensuring the threat kill. A secondary short-range anti-ship capability is also provided by the Rif system.
The Rif system has been designed to engage high speed aircraft and missiles flying at up to Mach 4 at long ranges, and surface ships such as carriers and electronic countermeasures ships. It employs the S-300 missiles (5V55?) embedded in the ship's hull like an VLS system. The ship's sensors and fire control systems provide the required data and support to effectively launch and direct the 5V55 missiles.
The Rif system has been designed to be integrated on ships featuring at least 8,000 tons of displacement. It was introduced in 1982 aboard Soviet cruisers.
The S-300F, SA-N-6 Grumble NATO-codename and Rif Russian nickname, is a derivative of proven S-300 Surface-to-Air Missile (SAM) system designed to protect surface ships against advanced airborne threats. The system can engage up to 6 targets simultaneously with 2 missiles per target ensuring the threat kill. A secondary short-range anti-ship capability is also provided by the Rif system.
The Rif system has been designed to engage high speed aircraft and missiles flying at up to Mach 4 at long ranges, and surface ships such as carriers and electronic countermeasures ships. It employs the S-300 missiles (5V55?) embedded in the ship's hull like an VLS system. The ship's sensors and fire control systems provide the required data and support to effectively launch and direct the 5V55 missiles.
The Rif system has been designed to be integrated on ships featuring at least 8,000 tons of displacement. It was introduced in 1982 aboard Soviet cruisers.
Shtil
The Shtil is a medium range, ship-based, Surface-to-Air Missile (SAM) system designed to engage multiple targets simultaneously. It is a derivative of the proven Buk-M1 air defense system. It can engage supersonic aircraft and anti-ship missiles flying at a maximum speed of Mach 2.5. Up to 12 9M38 missiles can be launched simultaneously employing 8 antenna sets.
The Shtil SAM system uses the information provided by the ship 3D radar system. It has been highly automated to reduce the reaction time in the event of an attack. The 9M38 missile are fired employing a ramp, 24 (1 ramp system) to 96 (4 ramps) 9M38 missiles can be associated to the Shtil system.
The Shtil is a medium range, ship-based, Surface-to-Air Missile (SAM) system designed to engage multiple targets simultaneously. It is a derivative of the proven Buk-M1 air defense system. It can engage supersonic aircraft and anti-ship missiles flying at a maximum speed of Mach 2.5. Up to 12 9M38 missiles can be launched simultaneously employing 8 antenna sets.
The Shtil SAM system uses the information provided by the ship 3D radar system. It has been highly automated to reduce the reaction time in the event of an attack. The 9M38 missile are fired employing a ramp, 24 (1 ramp system) to 96 (4 ramps) 9M38 missiles can be associated to the Shtil system.
Albatros - Albatros
Albatros is a ship-based air defense system based on Aspide and Aspide 2000 surface-to-air missiles which are stored in four-cell launcher/canister. It may be deemed as the Italian counterpart to US Navy's Sea Sparrow short range air defense system. Aspide is a derivative of AIM-7 Sparrow missile. Albatros is intended primarily to provide self-defense against airborne threats such as aircraft and cruise missiles.
The Italian Navy has deployed Albatros on many of its surface ships including Giuseppe Garibaldi aircraft carrier, Maestrale, Artigliere, Durand de la Penne and Minerva-class frigates.
Albatros is a ship-based air defense system based on Aspide and Aspide 2000 surface-to-air missiles which are stored in four-cell launcher/canister. It may be deemed as the Italian counterpart to US Navy's Sea Sparrow short range air defense system. Aspide is a derivative of AIM-7 Sparrow missile. Albatros is intended primarily to provide self-defense against airborne threats such as aircraft and cruise missiles.
The Italian Navy has deployed Albatros on many of its surface ships including Giuseppe Garibaldi aircraft carrier, Maestrale, Artigliere, Durand de la Penne and Minerva-class frigates.
卡什坦
等等我接着爬
好了,来点以色列的吧
箭来了
:D :D :D
不错哦,继续看:D
呵呵,好多船
大家都 可以认认哦,不少都 是 我们看得不能再看的了
箭长得真丑。。。。。。。